Infection Monkey ==================== ### Data center Security Testing Tool ------------------------ Welcome to the Infection Monkey! The Infection Monkey is an open source security tool for testing a data center's resiliency to perimeter breaches and internal server infection. The Monkey uses various methods to self propagate across a data center and reports success to a centralized C&C server. To read more about the Monkey, visit https://www.guardicore.com/infectionmonkey/ ### http://www.guardicore.com/the-infected-chaos-monkey/ Features include: * Multiple propagation techniques: * Predefined passwords * Common exploits * Multiple propagation protocols: * SSH * SMB * RDP * A C&C server with a dedicated UI to visualize the Monkey's progress inside the data center Getting Started --------------- The Infection Monkey is comprised of two parts: the Monkey and the C&C server. The monkey is the tool which infects other machines and propagates to them, while the C&C server collects all Monkey reports and displays them to the user. ### Requirements The C&C Server has been tested on Ubuntu 14.04. The Monkey itself has been tested on Windows XP, 7, 8.1 and 10. The Linux build has been tested on Ubuntu server 14.04 and 15.10. ### Installation For off-the-shelf use, download our pre-compiled binaries from our website. To set up the C&C server follow the instructions on [Monkey Island readme](monkey_island/readme.txt). If you wish to compile the binaries yourself, follow the instructions under Building the Monkey from Source. ### Initial configuration. Whether you're downloading or building the Monkey from source, the Infection Monkey is comprised of 4 executable files for different platforms plus a default configuration file. Monkey configuration is stored in two places: 1. By default, the Monkey uses a local configuration file (usually, config.bin). This configuration file must include the address of the Monkey's C&C server. 2. After successfully connecting to the C&C server, the monkey downloads a new configuration from the server and discards the local configuration. It is possible to change the default configuration from the C&C server's UI. In both cases the command server hostname should be modified to point to your local instance of the Monkey Island (note that this doesn't require connectivity right off the bat). In addition, to improve the Monkey's chances of spreading, you can pre-seed it with credentials and usernames commonly used. Both configuration options use a JSON format for specifying options; see "Options" below for details. ### Running the C&C Server To run the C&C Server, install our infected Monkey debian package on a specific server. The initial infected machine doesn't require a direct link to this server. ### Unleashing the Monkey Once configured, run the monkey using ```./monkey-linux-64 m0nk3y -c config.bin -s 41.50.73.31:5000``` (Windows is identical). This can be done at multiple points in the network simultaneously. Command line options include: * `-c`, `--config`: set configuration file. JSON file with configuration values, will override compiled configuration. * `-p`, `--parent`: set monkey’s parent uuid, allows better recognition of exploited monkeys in c&c * `-t`, `--tunnel`: ip:port, set default tunnel for Monkey when connecting to c&c. * `-d`, `--depth` : sets the Monkey's current operation depth. How the Monkey works --------------------- 1. Wakeup connection to c&c, sends basic info of the current machine and the configuration the monkey uses to the c&c. 1. First try direct connection to c&c. 2. If direct connection fails, try connection through a tunnel, a tunnel is found according to specified parameter (the default tunnel) or by sending a multicast query and waiting for another monkey to answer. 3. If no connection can be made to c&c, continue without it. 2. If a firewall app is running on the machine (supports Windows Firewall for Win XP and Windows Advanced Firewall for Win 7+), try to add a rule to allow all our traffic. 3. Startup of tunnel for other Monkeys (if connection to c&c works). 1. Firewall is checked to allow listening sockets (if we failed to add a rule to Windows firewall for example, the tunnel will not be created) 2. Will answer multicast requests from other Monkeys in search of a tunnel. 4. Running exploitation sessions, will run x sessions according to configuration: 1. Connect to c&c and get the latest configuration 2. Scan ip ranges according to configuration. 3. Try fingerprinting each host that answers, using the classes defined in the configuration (SMBFinger, SSHFinger, etc) 4. Try exploitation on each host found, for each exploit class in configuration: 1. check exploit class supports target host (can be disabled by configuration) 2. each exploitation class will use the data acquired in fingerprinting, or during the exploit, to find the suitable Monkey executable for the host from the c&c. 1. If c&c connection fails, and the source monkey’s executable is suitable, we use it. 2. If a suitable executable isn’t found, exploitation will fail. 3. Executables are cached in memory. 5. will skip hosts that are already exploited in next run 6. will skip hosts that failed during exploitation in next run (can be disabled by configuration) 5. Close tunnel before exiting Wait for monkeys using the tunnel to unregister for it Cleanup Remove firewall rules if added Configuration Options --------------------- Key | Type | Description | Possible Values --- | ---- | ----------- | --------------- singleton_mutex_name | string | string of the mutex name for single instance | example: {2384ec59-0df8-4ab9-918c-843740924a28} alive | bool | sets whether or not the monkey is alive. if false will stop scanning and exploiting self_delete_in_cleanup | bool | sets whether or not to self delete the monkey executable when stopped use_file_logging | bool | sets whether or not to use a log file monkey_log_path_[windows/linux] | string | file path for monkey logger. timeout_between_iterations | int | how long to wait between scan iterations max_iterations | int | how many scan iterations to perform on each run victims_max_find | int | how many victims to look for in a single scan iteration victims_max_exploit | int | how many victims to exploit before stopping command_servers | array | addresses of c&c servers to try to connect | example: ["russian-mail-brides.com:5000"] internet_services | array | addresses of internet servers to ping and check if the monkey has internet acccess retry_failed_explotation | bool | sets whether or not to retry failed hosts on next scan range_class | class name | sets which ip ranges class is used to construct the list of ips to scan | `FixedRange` - scan list is a static ips list, `RelativeRange` - scan list will be constructed according to ip address of the machine and size of the scan, `ClassCRange` - will scan the entire class c the machine is in. scanner_class | class name | sets which scan class to use when scanning for hosts to exploit | `TCPScanner` - searches for hosts according to open tcp ports, `PingScanner` - searches for hosts according to ping scan finger_classes | tuple of class names | sets which fingerprinting classes to use | in the list: `SMBFinger` - get host os info by checking smb info, `SSHFinger` - get host os info by checking ssh banner, `PingScanner` - get host os type by checking ping ttl. For example: `(SMBFinger, SSHFinger, PingScanner)` exploiter_classes | tuple of class names | | `SmbExploiter` - exploit using smb connection, `WmiExploiter` - exploit using wmi connection, `RdpExploiter` - exploit using rdp connection, `Ms08_067_Exploiter` - exploit using ms08_067 smb exploit, `SSHExploiter` - exploit using ssh connection range_fixed | tuple of strings | list of ips to scan RelativeRange range_size | int | number of hosts to scan in relative range tcp_target_ports | list of int | which ports to scan using TCPScanner tcp_scan_timeout | int | timeout for tcp connection in tcp scan (in milliseconds) tcp_scan_interval | int | time to wait between ports in the tcp scan (in milliseconds) tcp_scan_get_banner | bool | sets whether or not to read a banner from the tcp ports when scanning ping_scan_timeout | int | timeout for the ping command (in milliseconds) utilised by PingScanner psexec_user | string | user to use for connection, utilised by SmbExploiter/WmiExploiter/RdpExploiter psexec_passwords | list of strings | list of passwords to use when trying to exploit skip_exploit_if_file_exist | bool | sets whether or not to abort exploit if the monkey already exists in target, used by SmbExploiter rdp_use_vbs_download | bool | sets whether to use vbs payload for rdp exploitation in RdpExploiter. If false, bits payload is used (will fail if bitsadmin.exe doesn’t exist) ms08_067_exploit_attempt | int | number of times to try and exploit using ms08_067 exploit ms08_067_remote_user_add | string | user to add to target when using ms08_067 exploit ms08_067_remote_user_pass | string | password of the user the exploit will add ssh_user | string | user to use for ssh connection, used by SSHExploiter ssh_passwords | list of strings | list of passwords to use when trying to exploit using SSHExploiter Building the Monkey from source ------------------------------- If you want to build the monkey from source instead of using our provided packages, follow the instructions at the readme files under [chaos_monkey](chaos_monkey) and [monkey_island](monkey_island). License ======= Copyright (c) 2016 Guardicore Ltd See the [LICENSE](LICENSE) file for license rights and limitations (GPLv3). Dependent packages --------------------- Dependency | License | ----------------------------|---------------------------- libffi-dev | https://github.com/atgreen/libffi/blob/master/LICENSE PyCrypto | Public domain upx | Custom license, http://upx.sourceforge.net/upx-license.html bson | BSD enum34 | BSD pyasn1 | BSD psutil | BSD flask | BSD flask-Pymongo | BSD Flask-Restful | BSD python-dateutil | Simplified BSD zope | ZPL 2.1 Bootstrap | MIT Bootstrap Switch | Apache 2.0 Bootstrap Dialog | MIT JSON Editor | MIT Datatables | MIT jQuery | MIT cffi | MIT twisted | MIT typeahead.js | MIT Font Awesome | MIT vis.js | MIT/Apache 2.0 impacket | Apache Modified Start Bootstrap (UI Theme) | Apache 2.0 requests | Apache 2.0 odict | Python Software Foundation License paramiko | LGPL rdpy | GPL-3 winbind | GPL-3 pyinstaller | GPL Celery | BSD